Power converter having temperature compensated output power

ABSTRACT

A power converter reducing a maximum available output power during extreme operating temperature conditions. The output power is adapted to be reduced during higher operating temperatures to maintain the power converter housing within acceptable operating temperatures. The power converter may then increase the available operating power as the converter housing temperature is reduced such that an acceptable output power is available during higher operating temperatures, rather than simply turning off the power converter during the excessive temperature condition.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a Continuation of U.S. patent application Ser. No. 11/213,117 filed Aug. 26, 2005, entitled “AC/DC Power Converter” which is a continuation of U.S. patent application Ser. No. 10/790,654 filed Mar. 1, 2004, entitled “Dual Input AC And DC Power Supply Having A Programmable DC Output Utilizing A Secondary Buck Converter” now U.S. Pat. No. 6,937,490, which is a Continuation of U.S. patent application Ser. No. 10/072,074 filed Feb. 8, 2002, entitled “Dual Input AC And DC Power Supply Having A Programmable DC Output Utilizing A Secondary Buck Converter” now U.S. Pat. No. 6,700,808 which is a CIP of U.S. patent application Ser. No. 10/005,961 filed Dec. 3, 2001 now U.S. Pat. No. 6,643,158, entitled “Dual Input AC/DC To Programmable DC Output Converter” which claims priority of U.S. Provisional Patent Application Ser. No. 60/335,785, filed Oct. 31, 2001, the teachings of which are incorporated herein by reference.

TECHNICAL FIELD

The present invention generally relates to the field of power converters, and more particularly to a dual input AC and DC to programmable DC output power converter.

BACKGROUND OF THE INVENTION

As the use of mobile electronic products, such as PC notebooks, PDAs, cellular telephones and the like, continues to increase, the need for low cost, compact power supplies to power and recharge these products also continues to increase. Most manufacturers of mobile products typically include plug-in power adapters along with these mobile products to help facilitate the power supply needs of their customers.

Today's power adapters are typically AC-to-DC, or DC-to-DC power converters which are configured to either step-up or step-down the DC voltage input delivered to the mobile device. With AC-to-DC adapters, for example, users can power most mobile devices by simply plugging the adapter into a simple AC wall outlet commonly found in most homes or offices. Similarly, when only DC input power is available, such as in an automobile or airplane, users can still power their mobile devices by simply using a standard, off-the-shelf DC-to-DC adapter. Normally, both adapters are designed and tailored to provide a regulated DC output voltage, which typically range from between 5VDC to 30VDC depending on the kind of mobile device being powered.

Although these power adapters conveniently provide direct power and recharging capabilities, users are often required to carry separate adapters to provide power to each individual mobile device. This often means that users have to carry multiple adapters: one for an AC input power source, and another for a DC input power source, moreover, users typically carry multiple adapters to power multiple devices. Thus, by carrying more than one device at a time, users of mobile product users are forced to carry more than one bulk power supply adapter.

Accordingly, there exists a need for a power converter that resolves the system management problems associated with carrying all of the different power supply components necessary to power a wide variety of mobile or portable devices. Moreover, such a power converter would advantageously encompass serving the power supply needs of several different mobile devices, as it would supply a filtered and regulated DC output voltage in response to either an AC and DC input voltage. Moreover, by having a power convert or having multiple output terminals, users have the ability of providing power to several mobile devices of varying power requirements, simultaneously, regardless of whether the input voltage is AC or DC.

There is also a need for a power converter which is operable during excessive temperature conditions, and which reduces the likelihood the power converter will completely turn off due to excessive operating temperature.

SUMMARY OF THE INVENTION

The present invention achieves technical advantages as a power converter reducing a maximum available output power during extreme operating temperature conditions. The output power is adapted to be reduced during higher operating temperatures to maintain the power converter housing within acceptable operating temperatures. The power converter may then increase the available operating power as the converter housing temperature is reduced such that an acceptable output power is available during higher operating temperatures, rather than simply turning off the power converter during the excessive temperature condition.

BRIEF DESCRIPTION OF THE DRAWINGS

Advantages of the invention and the specific embodiments will be understood by those of ordinary skill in the art by reference to the following detailed description of preferred embodiments taken in conjunction with the drawings, in which:

FIG. 1A shows a block diagram of a dual input AC and DC power converter having dual DC voltage outputs in accordance with the present invention;

FIG. 1B shows an exploded view of the converter with the detachable buck circuit;

FIG. 2 shows a schematic diagram of the power converter circuit as illustrated in FIG. 1 in accordance with the present invention;

FIG. 3 shows a detailed schematic diagram of a DC-to-DC buck converter circuit in accordance with the present invention; and

FIG. 4 shows a detailed schematic diagram of the power converter circuit according to a second preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The numerous innovative teachings of the present applications will be described with particular reference to the presently preferred exemplary embodiments. However, it should be understood that this class of embodiments provides only a few examples of the many advantageous uses and innovative teachings herein. In general, statements made in the specification of the present application do not necessarily delimit any of the various claimed inventions. Moreover, some statements may apply to some inventive features, but not to others.

There is shown in FIG. 1A a block diagram of a dual input AC/DC power converter 10 having dual programmable DC voltage outputs in accordance with the present invention. Preferably, the dual input AC/DC power converter 10 comprises a power converter circuit 20 having an AC-to-DC converter 22, a DC-to-DC booster converter 24, a feedback circuit 26, a filter circuit 25 and a DC-to-DC buck converter 28. The power converter circuit 20 is seen housed in housing 13 and advantageously provides a first programmable DC output voltage at DC output terminal 16 and a second programmable DC output voltage at terminal 18. Both of these DC output voltages may be generated as a function of both AC and DC input voltages.

In operation, the AC-to-DC converter 22 receives an AC signal via input terminal 12 and provides a regulated DC output voltage at node N1. Similarly, the DC-to-DC booster converter 24 may receive a DC input voltage at its input via input terminal 14 and may also provide a regulated DC output voltage at node N1.

Input terminals 12 and 14 are integrated into a single common connector 17 such that different power cords adapted to receive input power from different sources are received by the common connector 17. For instance, DC power from an airplane or car power source are wired to couple to input 12 and AC source is wired to couple to input 14. In a selected embodiment, the AC-to-DC converter 22 is adapted to generate a DC output voltage of between 15VDC and 24VDC in response to an AC input voltage at terminal 12 ranging between 90VAC and 265VAC. Likewise, the DC-to-DC booster converter 24 is adapted to provide a DC output voltage which is substantially similar to that of converter 22, but which is generated in response to a DC input voltage supplied at input terminal 14. Preferably, DC-to-DC booster converter 24 is adapted to receive a voltage in the range of between 11VDC and 16VDC. Advantageously, AC-to-DC conversion, via AC-to-DC converter 22, allows users of the power converter 10 to power high-power mobile devices, such as a laptop computer wherever AC input power is available, such as in the home or office, for example. Conversely, the DC-to-DC booster converter 24 of the power converter 10 is capable of powering similar high-power devices by stepping up most low amplitude DC input signals, such as those found in automobile and/or airplane environments.

As shown, filter circuit 25 has its input tied to the respective outputs of the converter 22 and 24. In a preferred embodiment, the filter circuit is adapted to provide a filtered DC output voltage at second node N2, which, thereafter, feeds output terminal 16, at an output power of 75 watts, for example.

The single feedback circuit 26 is shown coupled to the output of filter circuit 25 at node N2. In a preferred embodiment, the feedback 26 circuit, through a single feedback loop, regulates the voltage level of the filtered DC output voltages generated by both converters 22 and 24. This single feedback loop regulate both converters 22 and 24 via photodiodes PH1 and PH3 by coupling the feedback signal to each feedback pin 1 of the respective PWM circuit IC1 and IC2, as shown. Additionally, the feedback circuit 26 is adapted to receive a removable programming module that allows mobile device users to provide a selectable DC output voltage at output 16 via node N2. The programming module comprises a key (tip) 15 comprising a resistor, wherein different associated values of the resistor establish different associated DC output voltages at output 16. By allowing users to selectively change the voltage level of the filtered DC output voltage, the power converter 10 may be adapted to power a variety of different mobile electronic devices, such as through the key (tip) 15, having different associated power requirements. Moreover, the power converter's 10 programming module may also be adapted to provide the additional function of output current limiting.

The DC-to-DC buck converter 28 has its input coupled at node N2, providing a second DC output voltage that is then fed to output terminal 18, having an output power of 10 watts, for example. Preferably, buck converter 28 discreetly steps down the filtered DC voltage and produces a second DC output voltage at a separate output terminal 18. In a selected embodiment, the buck converter 28 steps down the filtered DC output voltage to a range of about 3VDC and 15VDC. Advantageously, this second DC output voltage generated by converter 28 is independent of, and substantially lower than the DC output voltage at terminal 16. This allows users of the present invention to power not only a high-power peripheral, such as a laptop computer, but also, a second, low-power peripheral, such as a cell phone, PDA, and the like. Moreover, the present invention allows for these peripherals to be powered simultaneously by a single converter, regardless if the input voltage is AC or DC. The buck converter 28 is physically detachable from the main housing 13 as shown in FIG. 1B, allowing different buck circuits providing different output voltages to be selectively attached to housing 13 and tap the DC output voltage from output terminal 18.

Referring now to FIG. 2 there is shown a schematic diagram of the power converter circuit 20 of the dual input AC/DC power converter 10 as depicted in FIG. 1 in accordance with an exemplary embodiment of the present invention. As described herein in greater detail, the power converter circuit 20, in a preferred embodiment, comprises three separate converters: AC-to-DC power converter 22, DC/DC boost converter 24, and DC-to-DC buck converter 28.

AC-to-DC Converter

The AC-to-DC power converter 22 includes a true off line switcher which is configured in a fly-back topology. Full-wave rectification of an AC input signal, received at input terminal 12, occurs using a full-wave bridge rectifier BD1 and a filter capacitor C1, which creates a DC voltage bus from which the switcher operates. Inductor L1 offers additional EMI filtering of the AC signal after the signal has been rectified through the full-wave bridge. The AC-to-DC converter 22 also includes a main controller IC1 configured as a current mode pulse-width modulator (PWM). Main controller IC1 is also configured to have a single-ended output with totem pole driver transistors coupled thereto. The AC-to-DC power converter 22 has a main power switch Q1 which drives the main transformer T1. In a preferred embodiment, the transformer T1, Schottky diode D11, and filter capacitors C24 and C25 combine to provide the DC output voltage at node N1.

As noted earlier, filter circuit 25 allows for additional filtering of the DC output voltage derived from node N1. The filter circuit 25 itself comprises inductor L3, capacitor C26 and transformer NF1. Advantageously, the filter circuit 25 produces a filtered DC output voltage at output 16 having less than 100 mv peak-to-peak noise and ripple.

The feedback circuit 26, through the single feedback loop, regulates the filtered DC output voltages provided by the converters 22 and 24. The feedback circuit 26 is also adapted to be coupled to a removable programming module having a key 15, comprising resistor R53. As such, the present invention allows users to selectively program the DC output voltage later received at output terminal 16. The feedback circuit 26 includes a photocoupler circuit comprising a pair of photocouplers PH1 and PH3 connected in series (i.e., stacked), each being coupled to the outputs of operational amplifiers IC4-A and IC4-B. Advantageously, these photocouplers are arranged along the feedback loop of the feedback circuit 26. Additionally, the feedback circuit 26 efficiently regulates the filtered DC output voltages generated by both converters 22 and 24 through a single feedback loop. In stacking the photo-couplers, the present invention also allows the power converter 10 to maintain proper input/output isolation between respective terminals 12 and 14 and output terminal 16.

Preferably, the output current limiting function of converter 22 is accomplished via integrated circuit IC4A, resistors R33, R37, R38, and R39 and programming resistor R54.

Over voltage protection of AC-to-DC converter 22 is achieved using photocoupler PH2 and zener diode ZD2. In a preferred embodiment, zener diode ZD2 is set at 25V such that when in avalanche mode it causes the transistor side of photocoupler PH2 to bias transistor Q1 into the on state. When it is the on state, transistor Q3 pulls low pin 1 of integrated controller IC1 and pulls the operating duty cycle of the integrated controller towards 0%. This takes the DC output voltage to 0 volts. Also, when transistor Q1 is on, transistor Q2 is also forced on which then forces these two transistors become latched. If transistors Q1 and Q2 are latched, input power must be recycled in order for the power converter 10 to be turned on again.

DC-to-DC Converter

The DC-to-DC converter 24 is configured in a boost topology and utilizes the same kind of integrated controller, IC2, as used in converter 22. In the DC-to-DC converter 24, transistor Q8 acts as the main power switch and diode D6 as the main rectifier. Preferably, inductor L2 is adapted to function as a power boost inductor, which is comprised of a toroid core-type inductor. It should be understood that the cathode leads of diodes D11 and D8 are connected, forming an ORed configuration, requiring only one output filter. Advantageously, this eliminates the board space needed for a second set of filters capacitors.

Like the AC-to-DC converter 22, the DC-to-DC converter 24 is also designed to operate at a frequency of around 80 KHZ. For the AC-to-DC converter 22, the operating frequency is set by resistor R13 and capacitor C7. Likewise, the operating frequency of the DC-to-DC converter 24 are set by resistor R28 and capacitor C28.

The DC-to-DC converter 24 includes an over-voltage protection circuit comprising zener diode ZD2, resistor R23, R24, R48, transistor Q415, and silicon-controlled rectifier SC1. Zener diode ZD2 sets the over-voltage protection point (OVP) which is preferably set at 25VDC. Generally, there is no current flowing through resistor R48. If, however, when zener diode ZD2 begins to conduct current, the drop across R48 is significant enough to bias transistor Q6 on, pulling its collector terminal high, and thereby turning silicon controlled rectifier SC1 on. When silicon control rectifier SC1 is on, it pulls pin 1 of the integrated controller IC2 low. Thus, if pin 1 of integrated controller IC2 is low, the output drivers thereof are forced to operate at a duty cycle of 0%, thereby producing a DC output voltage of 0 volts at pin 6. Advantageously, the silicon controlled rectifier SC1 functions as a power latch circuit that requires that input power be recycled in order to turn on the power converter 10 if a voltage above 25VDC is detected at node N1.

The temperature of the housing 13 of the power converter 10 is monitored using a thermistor NTC3. If, for example, there is a corresponding increase in the temperature of the housing 13, it will result in a decrease in the resistive value of thermistor NTC3, thereby causing transistor Q9 to turn on and pull low pin 1 of integrated circuit IC2 of converter 24. Moreover, this causes the photo-coupler PH2 to be biased enough to activate a latch circuit comprising transistors Q1 and Q2 that will shutdown the power converter 22. In addition, the power converter's 10 thermal protection feature is adapted to operate regardless of whether an AC or DC input voltage is being received at their respective input terminals.

FIG. 3 shows a detailed schematic diagram of the DC-to-DC buck converter 28 in accordance with the present invention. The buck converter 28 has an integrated circuit controller IC1, similar to converters 22 and 24, which is adapted to generate an on-time duty cycle to power transistor switch Q1. The operating frequency of controller IC1 is set by capacitor C6, which is coupled between pin 4 of IC1 and ground, and resistor R1, which is coupled between pins 4 and 8. In a selected embodiment, the diode D1 functions comprise a Schottky diode and functions as “catch” diode. Inductor L1 is a output power inductor and couples the gate of power transistor Q1 to V_(out). Fuse F1 is shown coupled between V_(in) and the drain terminal of power transistor Q1, and advantageously provides current protection to buck-converter 28.

Furthermore, the input V_(in) of the buck converter 28 is coupled to the output of filter circuit 25 at node N2, wherein V_(in) receives the filtered DC output voltage therefrom. In a preferred embodiment, the input of the buck converter 28 is coupled to output terminal 18 and provides a second DC output voltage at V_(out). Advantageously, the buck converter 28 discreetly steps down the filtered DC output voltage and provides a second DC output voltage at output terminal 18 which is independent of, and substantially lower than the DC output voltage at output terminal 16. A cable is not required to be connected to output 18 for buck converter 28 to operate. Likewise, the DC output voltage of the buck converter 28 enables users low-power peripherals, such as, a cell phones, a PDAs, and/or similar mobile devices. In a selected embodiment, the buck convert 28 may also be adapted to provide a DC output voltage at output terminal 18 ranging between 3VDC and 15VDC, selectively determined as a function of the chosen value of resistor R1 used in the particular buck converter 28, with a total power delivery of 10 watts, for example. As previously mentioned, the buck converter 28 may be housed in a separate, detachable program module that enables users to selectively program the DC output voltage at terminal 18 as a function of different associated buck converter modules.

Referring now to FIG. 4, there is shown a detailed electrical schematic of a converter circuit 40 according to another preferred embodiment of the present invention. Circuit 40 is similar in many regards to that shown in FIG. 2 and described earlier, wherein like numerals refer to like elements, and contains some further features which will now be described. In this embodiment, the temperature of the power converter housing 13 housing this circuit 40 is also monitored using a thermistor NTC3 coupled thereto. However, in this embodiment, when there is an increase in the temperature of the housing 13, the resistive value of thermistor NTC3 will correspondingly decrease as a function of the housing temperature, and the output power generated by circuit 40 continues to be provided, but at a reduced power being a function of the housing temperature. Thus, when the housing 13 heats up to a predetermined temperature, the power output of the circuit 40 will responsively begin to decrease, such that the reduction in the output power reduces the housing temperature of the housing 13 to maintain the temperature within a safe operating range, such as below a maximum temperature (threshold) established by regulatory agencies. If the housing temperature continues to increase, converter circuit 40 responsively continues to decrease the output power available by converter circuit 40. Should the operating temperature of housing 13 eventually exceed the maximum temperature allowed, such as set forth by regulatory agencies, the converter circuit 40 will then responsively shut down. The power converter will remain shut down until the power converter is reset by the user, such as by removing the input power from the converter, and then reconnecting the input power to the converter, such as by removing and reattaching the input power cord to the converter.

Still referring to FIG. 4, these features of circuit 40 are established, in part, by the combination of thermistor NTC3 and resistor R79 forming a resistive divide network with a node T defined therebetween. At a nominal housing 13 operating temperature of, for instance, 25° Celsius, the resistive value of thermistor NTC3 may be 100K Ohms. In contrast, if the housing 13 should have an operating temperature of about 86° Celsius, the value of the thermistor NTC3 may be about 9 K Ohms. The thermistor resistance between 100 K Ohms and 9 K Ohms is generally linearly related to the operating temperature of the thermistor, and thus the housing 13. For instance, there is a 61° Celsius voltage swing (delta) between this nominal temperature and the maximum allowed operating temperature, and a 91K Ohms resistance swing (delta) over this temperature swing. Hence, should the operating temperature of the housing 13 be about 50° Celsius, the resistance of thermistor NTC3 maybe about 46.3K Ohms.

Current limit regulation in the power converter circuit 40 is provided by operational amplifier IC4-A, which op amp generates a feedback control signal to the DC/DC PWM IC2 via the feedback loop, and also to the AC/DC PWM IC1 the single feedback loop as previously described. Operational amplifier IC4-A provides current limit regulation, and operational amplifier IC4-B provides voltage regulation.

The output current sense function is provided by resistor R18, (Ejaz, confirm this designation) which resistor R18 creates a voltage level proportional to the associated output current level, and which voltage level is provided to the negative input of op amp IC4-A. When the voltage level causes the voltage at the negative input of IC4-A to exceed the threshold voltage V_(th) at the positive input of op amp IC4-A, the output voltage level of op amp IC4-A changes, and the converter circuit 40 responsively reduces the output power available at output 16.

The normal operating voltage level of threshold voltage V_(th) is established by the value of resistor R37, divided by the sum of resistors R37, R39, and R71, times the reference voltage established by op amp IC5. Essentially, the voltage at node R is established by the resistive divide network formed by resistors R37, R39 and R71. For instance, if R37 has a value of 1.15K Ohms, R39 has a value of 110K Ohms, and resistor R71 has a value of 33K Ohms, and the reference voltage established by op amp IC5 is 2.5 volts, then the reference voltage provided at node R and to the positive input of op amp IC4-A is about 19.4 mV.

By way of example, in an excessive operating temperature condition where temperature sensor NTC3 has reduced in value from 100K Ohms at 25° Celsius to about 9K Ohms at 86° Celsius (first threshold), the combination of thermistor NTC3 and resistor R78 responsively will forward-bias diode IC7 such that the voltage at the nodes is responsively reduced, with a proportional reduction of the voltage of reference V_(th) at node R. Any further increase in the temperature of thermistor NTC3 beyond this first threshold will consequently result in a further decrease of reference voltage V_(th) at node R such that the output power of circuit 40 available at output 16 will correspondingly continue to decrease. Advantageously, the available overall output power of circuit 40 will thus reduce the temperature of housing 13 such that it remains within its rated temperature limit.

In the event of a catastrophic condition, such as where the temperature of housing 13 continues to rise after output power has been reduced in half, then the voltage at node T will responsively bias transistor Q15, thus biasing transistor Q9, which in turn provides a ground to node W, thereby biasing diode PH2 which biases transistor Q4, and the circuit 40 shuts down thereby providing over voltage protection (OVP).

The embodiment shown in FIG. 4 provides the advantages of reducing the output power provided by the power converter when the temperature of the housing 13, which is physically coupled to thermester NTC3, exceeds the first threshold, such as 86° Celsius. Any further increase in housing temperature thereafter will correspondingly further reduce the output power of the converter 10 to help reduce the operating temperature of the circuit 40 and thus the housing 13. Thus, the available output power is variable and a function of the housing temperature. If the nominal output power of circuit 40 is, for example, 70 watts, the available output power of circuit 40 that can be drawn by a portable electronic device via output 16 will continue to decrease down to about 35 watts when the housing 13 is at the maximum allowed operating temperature, such as 100° Celsius (second threshold). If the housing temperature exceeds this second threshold, then the circuit 40 completely shuts off, and manual resetting of the power converter circuit is required by the operator before the converter circuit can be powered on again, as previously described.

Though the invention has been described with respect to specific preferred embodiments, many variations and modifications will become apparent to those skilled in the art upon reading the present application. It is therefore the intention that the appended claims be interpreted as broadly as possible in view of the prior art to include all such variations and modifications. 

1. A power converter, comprising: a first circuit configured to an AC input voltage to a first DC voltage; a second circuit configured to a DC input voltage to a second DC voltage; a temperature sensor configured to generate a signal as a function of a temperature; and a third circuit configured to receive the first and second DC voltages and, in response thereto, provide a DC output voltage at an output, wherein the third circuit is configured to provide a maximum available output power as a function of the temperature sensor signal.
 2. The power converter as specified in claim 1 wherein the third circuit is configured to reduce the maximum available output power as the temperature sensor senses the temperature exceeding a first predetermined temperature.
 3. The power converter as specified in claim 1 further comprising a housing, the third circuit being disposed in the housing.
 4. The power converter as specified in claim 3 wherein the temperature sensor is coupled to the housing.
 5. The power converter as specified in claim 4 wherein the third circuit is configured to reduce the maximum available output power as a function of the housing temperature.
 6. The power converter as specified in claim 5 wherein the third circuit is configured to variably reduce the maximum available output power as a function of the temperature.
 7. The power converter as specified in claim 6 wherein the third circuit is configured to reduce the maximum available output power to zero when the temperature exceeds a second predetermined temperature being greater than the first predetermined temperature. 